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Optical Transport Network (OTN)

Optical Transport Network (OTN). ITU-T standard G.709 Paper: Andreas Schubert: ”G.709 – The Optical Transport Network (OTN)” http://www.jdsu.com/product-literature/g709otn_wp_opt_tm_ae.pdf. Overview. Literature Motivation for an optical transport network standard Properties of OTN

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Optical Transport Network (OTN)

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  1. Optical Transport Network (OTN) ITU-T standard G.709 Paper: Andreas Schubert: ”G.709 – The Optical Transport Network (OTN)” http://www.jdsu.com/product-literature/g709otn_wp_opt_tm_ae.pdf

  2. Overview • Literature • Motivation for an optical transport network standard • Properties of OTN • G.709 Interface standard • OTN framing structure - whats the point of all this overhead. • Tandem connection monitoring • Forward Error Correction (FEC)

  3. Literature • ITU-T • G.709 “Interface for the optical transport network (OTN)” • The most referenced standard in OTN • Describes Intra and inter –domain interfaces • Framing and framing structure • G.872 - Architecture of optical transport networks • Described from a network level viewpoint • Describes network layers • Andreas Schubert “White paper” • What is a white paper? • G.709 - The Optical Transport Network (OTN)

  4. Why not IP directly over WDM? • IP-WDM, a buzzword from the late 90’s • Can you transport an IP-packet directly on a fiber? • Which functionality is required? • 1……….. • 2…. • 3.. • 4..

  5. Why not IP directly over WDM? • IP-WDM, a buzzword from the late 90’s • Can you transport an IP-packet directly on a fiber? • Which functionality is required? • 1 Clock information • 2 Start/stop indication of packet • 3 Error checking? • 4 Error correction?

  6. Functionality added to IP for WDM transport • Framing for the physical layer transport • May e.g. be Ethernet • Monitoring of errors and signal quality • Management for provisioning of data-paths • Fault handling, fast protection • Management of wavelengths • Management of optical network elements • Functionality at the physical layer

  7. Why OTN? • Standard for optical networks required • Optical interconnection between equipment from different vendors • Optical interconnection between different operators • Once called “digital wrapper” • Framing of different protocols for transport over the physical optical layer • E.g. IP/Ethernet or IP/ATM or SDH • Takes SDH/SONET further, enabling optical functionality • From a single to multiple wavelengths • Forward Error Correction (FEC) • What is FEC?

  8. Properties of OTN • Protocol transparency • Handles “any” protocol-stack and gives a physical layer to higher layer protocols like e.g. IP • Backward compatibility for existing protocols • Handles both SDH and Ethernet • FEC • Reduces cost, improves performance • Reduction of 3R regeneration • Allows management of all-optical network elements

  9. Interfaces • Inter-domain interfaces (IrDI) • Location between networks of two operators • Location between sub-networks of two vendors in the same operator domain • The location within the sub-network of one vendor • 3R regeneration – Why? • Intra-Domain interfaces (IaDI) • The location between the equipment of an individual manufacturer’s sub-network • Transparent network

  10. Inter and intra -domain • Intra- IaDI within e.g. an operator • Inter- IrDI between operators or connection to e.g. a customer (client)

  11. Transport of a client signal • Over-Head (OH) added to form optical channel payload unit (OPU) • OH to OPU forming optical channel data unit (ODU) • Additional OH plus FEC are added to form the optical channel transport unit (OTU) • Adding further OH creates an OCh which is carried by one color

  12. OTN layer structure • OCh = Optical channel • OMS = Optical Multiplex section • OTS = Optical Transmission Section

  13. OTN hierarchy Client Client OPU Client OH ODU OH OPUk OTU OH ODUk FEC OChannel OCh payload Non Associated overhead OCC OCCp OCCp OCCp OCCp OCCp OMS payload OTS payload

  14. In-band and out of band OH • Non-associated OH (out of band) may be added to OCh enabling management of multiple colours in OTN. • Optical Multiplex Section (OMS) • Multiplex of OCh’s • Optical Transmission Section (OTS) • The transmission medium, I.e. the fibre

  15. Optical channel structure (OCh) 1 16 8 17 14 3825 15 7 3824 4080 OTU-OH Client FEC FAS 1 2 ODU-OH OPU-OH 3 4 PSI TCM6 TCM4 TCM5 RES FTFL PT TCM/ACT TCM3 EXP PM TCM2 TCM1 RES GCC1 RES GCC2 APS/PCC

  16. Optical Payload Unit (OPU) PSI • Framing of client signal • May be of any protocol, e.g. SONET/SDH, GFP, IP, GbE • Payload Structure Identifier (PSI) • 256 Byte message • Justification bits for asynchronous mapping of client signal • PSI0 contains Payload Type (PT) (single byte) identifying type of payload • RES – Bytes Reserved for future use PT RES

  17. Optical channel Data Unit (ODU) functionality • Tandem Monitoring (TCM) • Hierarchical error checking using parity bytes • Allows up to six tandem connections, nesting and overlapping • Path Monitoring (PM) • Monitoring of particular sections • Fault location • General Communication Channels (GCC) • Typically Management communication • Automatic Protection Switching (APS) • Protection switching at one or more levels • What is protection switching?

  18. ODU-k: Defined for several bitrates • -k is a number defining the bitrate • Originally defined bitrates • ODU1: 2.5 Gb/s • ODU2: 10 Gb/s • ODU3: 40 Gb/s • Recently defined/to be defined • ODU0: 1 Gb/s (Matches Gigabit Ethernet) • ODU4: 100 Gb/s (Matches 100 Gigabit Ethernet)

  19. ODU in OTN hierarchy Client Client OPU Client OH ODU OH OPUk OTU OH ODUk FEC OChannel OCh payload Non Associated overhead OCC OCCp OCCp OCCp OCCp OCCp OMS payload OTS payload

  20. ODU OH TCM6 TCM4 TCM5 RES FTFL TCM/ACT TCM3 EXP PM TCM2 TCM1 GCC1 RES GCC2 APS/PCC • PM - Path Monitoring, contains three sub-fields • TCM1-TCM6 • OH for six independent TCM’s • Contains similar sub-fields as PM • TCM/ACT Activation/deactivation of TCM • GCC • Communication between network elements (management), two channels • APS/PCC • Automatic Protection Switching • Protection Communication Channel • RES Reserved for future use • EXP Experimental use • FTFL - Fault Type and fault location Channel • Fault status, type and location • Related to TCM span

  21. Tandem Connection monitoring • Six levels, nested or cascaded connections • Nested: A1-A2/B1-B2/C1-C2 and A1-A2/B3-B4 Cascaded: B1-B2/B3-B4 • Carriers may maintain their own service level agreement (SLA) • What is a SLA? Figure from G.709 standard

  22. TCM and PM overhead structure Trail-Trace Identifier TTI BIP-8 Maintenance Signal present Parity Source access Point Identifier PM SAPI BEI STAT BDI Destination access Point Identifier DAPI Operator specific TCM BEI STAT BDI Backward Error Indication Info. Signal failure Upstream Single bit - Country of origin - Network operator - Administrative details

  23. FTFL sub-fields • Fault status information • Type and location of fault • Related to TCM span • Codes specified: No fault, Signal fail, signal degrade

  24. Optical channel transport unit (OTU) • Support transport of ODU via one or more optical channel connections • Frame alignment Signal (FAS) • Multi Frame Alignment Signal (MFAS) • Some ODU signals will span multiple OTU frames • TTI and TCM-ACT (activation) signals requires multiple ODU-frames for being processed • Forward Error Correction (FEC)

  25. OTU OH structure FAS OTU Comm. OTU term. Points (management) RES FAS MFAS GCC SM REServed For future use Section Monitoring = PM + IAE bit IAE: Ingress inform egress Incoming Alignment error on signal

  26. Forward Error Correction (FEC) 1 16 8 17 14 3825 15 7 3824 4080 OTU-OH Client FEC FAS 1 2 ODU-OH OPU-OH 3 • Added at the end of the OTU-frame • Very important property of OTN, why? • Detection of errors • Correction of errors through redundant information • Allows lower signal quality • I.e. allows larger degradation by physical impairments 4

  27. Physical impairments to be compensated • Linear (explain these) • Attenuation • Noise • Dispersion: Chromatic, mode and polarisation • Non-linear • Four wave mixing • Self phase modulation • Cross phase modulation

  28. FEC gain • Bit Error Rate (BER) improvement example: 10-4 -> 10-15 • How can BER be defined, and how is it measured? • Gain in power level approx 5 dB for 7 % FEC • Reduce amount of 3R regenerators • Use existing 2.5 Gb/s links for 10 Gb/s • Early warning when degradation of link quality start to appear • Longer spans between amplifiers in subsea-systems (lower cost)

  29. FEC algorithms • Performance increase depends on algorithm and amount of overhead (redundancy information) • Standardized algorithms, G.709. Reed-Solomon based

  30. Summary OTN • Management to the high bandwidth WDM network • SDH/SONET single wavelength, OTN – multiple wavelengths • Builds on management functionality from SDH/SONET • Monitoring functionality • GCC channels for management communication • Transparency to other protocols, e.g. IP • Wrap whatever you like • FEC compensates physical impairments, increases cost-efficiency

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